Computing-machine.



H. T, 6088 64 J. W. BRYCE.

COMPUTING MACHINE.

APPLICATION FILED OCT. 4. 1913.

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W/T/VESSES H. T. (5038 & J. W. BRYCE.

COMPUTING MACHINE.

APPLICATION FILED 0CT.4. 1913.

Patented Nov. 5, 1918.

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H. T. 6088 & J. W. BRYCE.

COMPUTING MACHINE.

APPLICATION FILED 0CT.4.19|3.

Patented Nov. 5.1918.

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WITNESSES ATTORNEYS H. T. GOSS & J. W. BRYCE.

COMPUTING'MACHINE.

APPLICATION mwocr. 4, 191's.

1 ,284, 188. Patented Nov. 5, 1918.

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COMPUTING MACHINE.

APPLICATION FILED OCT. 4. 1913.

Patented Nov. 5, 1918.

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COMPUTIN" MAQHINE.

APPLICATION FILED 0014. 1913.

Patented Nov.

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COMPUTING MACHINE.

APPLICATION FILED OCT. 4. 191a.

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COMPUTING MACHINE.

APPLICATION FILED 0014,1913.

Patented Nov. 5, 1918.

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INENTORJ W ATTORNEYS WITNESSES H. T. 6088 6L 1. W. BRYCE.

COMPUTING MACHINE.

APPLICATION FILED OCT. 4. ms.

Patented Nov. 5, 1918.

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lNl/ENTURS WITNESSES ww flll ATTORNEYS H. T. 6088 & J. W. BRYCE.

COMPUTING MACHlNE. APPLICATiON FILED OCT. 4. 1913.

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COMPUTING MACHINE. APPLICATION FILED 0014. 19x3 Patented Nov. 5,1918.

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H WITNESSES r uvmvrom $4 mm w MW fii, ATTORNEYS UNITED STATES PATENT OFFICE.

HARRY T.'GOSS, F RUTHERFORD, AN D JERSEY, ASSIGNORS To INTERNAT JAMES W. IBRYCE, OF BLOOMFIELD, NEW IONAL TIME RECORDING COMPANY OF NEW YORK, OF ENDICOTT, NEW YORK, A CORPORATION OF NEW YORK.

Comrormramaonmn.

Specification of Letters Patent.-

Patented Nov. 5,1971%;

Application filedpctober 4, 1913. Serial No. 793,283.

To all whom z'tmay concern:

. Be it knownthat we, HARRY T. Goss and JAMES W. Baron, both citizens of the United States, residing, respectively, at Rutherford, county of Bergen, and at Bloomfield, county of Essex, in the State of New Jersey, have invented certain new and useful Improve ments in Computing-Machines, of which the following is a full, clear, and exact description.-

This invention relates to calculating machines by' which numbers or items are added, subtracted, multiplied, or divided.

More particularly the invention in its present form relates to machines for multiplying factors at least oneof which is variable, and

its chief object is to provide for the purpose an improved apparatus of simple construction and operation. A further ob ect is toprovide a machine, particularly in connection with a scale for weighing goods, by whichthe product of the two factorsfor example the weight of the goods and the price thereof per unit weight-will .be displayed on numeral wheels or dials" as an integral or mixed number-and not merely on a graduated drum or dial as heretofore.

To these and other ends the invention in its preferred form is characterized by the employment of a movableor adjustable device which for conveniencemay be termed a controller or controlling element, for the reason that its chief function is to control or determine the operation of the numeral wheels so that they will present to view the correct product. This element may take various forms, as for example, a cone, or av cylinder, or arflatplate of polygonal or of circular ,contour, but in the preferred embodiment of the inventionthe element named is in the adjustable about its center. In general, the

controlling element bears all the products, up

to the maximum within the range of the ma chine; in particularit may bear only a part of each product, for example,the fractional part or the lower order or forders, leaving the; higher orders to be taken care of by an addltlonaland anilogous element. Thus in-the preferred em odiment, designed to give the product-in terms of dollars and cents (or, dollars and decimal fractions of 'aidol lar) the controlling form of a circular disk, rotatively provides for the cents and a suitable cam takes care of the dollars in determining the operation of the numeral wheels. In any case, where the product is given by means of numeral wheels, the controlling element, whether conical, cylindrical, or plane, etc., bears the products or parts thereof in the form of perforations, or projections, or the like, suitably arranged in one or more groupsior series, Thus in the case of a circular disk, there may be provided as many perforations or projections as there are units in the largest product provided for by the disk. For instance, if the disk is intended to take care of products up-to 300, it would have three hundred unit-perforations or projections, arranged in thirty groups or series, each having ten of theperforations, or projections. Similarly, the disk may have? thirty tensperforations or projections, in three groups or series of ten each, perforations or projections. tions, apertures, projections, or whatever they may be, are so arranged trolling element that when the latter is moved or adjusted, in accordance with the factors to be multiplied, only'one perforation or projection of each group or series The perforawill be presentedin position for coiipera tion with the mechanism of the numeral wheels.

Within the spirit of our invention, various methods may be employed .for controlling the movements of the numeral Wheels through the medium of the perforar tions or projections on the so-called controlling elementi For example, the wheels may be permitted to rotate until parts connected to, and moving with, the wheels are arrested by the particular perforations or projections presented for cooperation with such parts. Preferably, however, we provide what is herein conveniently. termed a pin-boxl, comprisinga frame having one or more rows of spring pins, When this device is moved toward the controlling element, one pin of eachrow finds a perforation in 'its path, which permits such pin to pass through the'controlling elementand into the-path of'a part which is connected and also three hundredon the cona to, and moves with. the particular numeral the pin in the path of the aforesaid part, while the other pins of the row pass on and out of such path.

In the preferred form of the invention, the operative movement of the controlling element is in one direction only, and the extent of its movement corresponds, in general, to the numerical value of the product of the factors to be multiplied.

In lieu of, or in addition to, the perforations, projections, or other agencies referred .to, the controlling element may have the various products marked upon it, by engraving, printing, or otherwise, so that the product may be read from the controlling element itself as well as from the numeral wheels, it such are provided.

Our invention also contemplates the use of printing devices, for instance numeralwheels provided with types; by which the result or product of the computation may be printed upon a suitable receiving surface, for example, a tape or card, but to avoid complicating the present application, such devices are not described herein. Inasmuch as multiplication is, fundamentally. only repeated addition, and subtraction and division are the reverse of addition and multiplication, respectively, the principles of our invention can be used for performing any of the four fundamental operations of arithmetic. \Ve have, however, deemed it sufficient to describe, in the present application, only machines for multiplying two factors.

Several convenient and effective forms of the invention are illustrated in the accompanying drawings, in which:

Figure 1 is a front view of the complete apparatus.

Fig. 2 is a rear view of the apparatus, but with a portion of the housing broken away to show certain interior parts.

Fig. 3 is a verticalsection substantially on line 33 of Fig. 4.

Figs. 1, 5 and 6 are vertical sections substantially on lines 44, 5-5 and 6-6 of Fig. 3.

Fi 7 is a horizontal section, about on line 77 of Fig. 3.

Fig. 8 is a detail view, partly in section, of the mechanism actuated or controlled by the scale pan.

Fig. 9 is a detached view of the pinbox and its actuating cam.

Fig. 10 is a detail sectional View of the yielding connection between the arm, which is controlled by the weight-of the material in the scale pan, and the manual operating mechanism.

Figs. 11 and 12 are detail plan and side views. respectively. of the pawl which locks the controlling arm after the latter is moved by the scale pan.

detailiaew of the pin-box and the controlling element (in the present instance a disk of sheet metal) by which the movements of the numeral wheels are controlled.

Fig. 14 is a detail view of the numeralwheel-actuating mechanism and the devices which, in cooperation with the controlling element and pin box, control the numeralwheels.

Fig. 15 is a front view of the controlling disk. and Fig. 16 is a central vertical section of the same.

Fig. 17 is a rear view of another embodiment of the invention. with a casing in section. In this embodiment the operation is almost wholly manual.

Fig. 18 is a vertical section substantially on'line. 18-18 of Fig. 17.

Fig. 19 is a front view of the embodiment shown in Fig. 17. with part of the casing broken away to show the controlling disk,

the pin-box, and other elements.

Fig. 20 is a section on line 2020 of Fig. 17.

Fig. 21 is a detail view of the pin-box actuating mechanism.

Fig. 22 is a front view of a still simpler embodiment. which ma'v be used for costkeeping and other purposes.

Fig. 23 is a vert cal section substantiallv on line 23-23 of Fig. 22.

Fig. 2% is a rear view of the embodinu-nt shown in Fig. 23, with the casing in vertical section.

Fig. 25 is a vertical section on line 25-25 of Fig. 24.

The operative parts of the machine are conveniently mounted in or upon a housing. consisting of a base 10 and an upright casing 11 at the front of-the former. The scale pan-'12. to receive the. goods to be weighed, is mounted ona stem 13 (Fig. 2). pivotally supported by the scale beam 11. one end of which is connected by a link 15 to a supplementary beam or lever 16. counter-we ghted at 16. which is in turn connected to the depending end of a pliable strap or tape 17 wrapped on an eccentric 18 mounted on a shaft 19 and pro ded with suitable counterwe ghts 20. 21. These counterweights are preferablv adjustable toward and from the axis of shaft 1 to scale in lmlance. Connected with the shaft is a pointer or index 22. traversing a graduated scale 23 upon which the weight mav be read when the pointer comes to rest. This scale is visible from the rear through a suit: able window 2t; and at the front is a similar scale 25 (Figs. 4 and'b). seen through a window 26. A pointer 27. fixed to and movable in un son. with the pointer 22 traverses the scale 25.

In general it is desirable. and in order to conform with the laws of some States and municipalities it is essential. that the scale out the to efi'ect this function while leaving the scale free at all times, 'but 'we prefer the mccha- 'nism now to be described. The mechanism ust referred to, shown in Figs. 3, 4, 7, 8

and 10, .includes a differential device consisting of a bevel gear 28 co-axial with and fixed to the eccentric 18,'a bevel gear 29 .loose onthe shaft 19, and two bevel pinions 30, 31, mounted on radial studs carried y a carrier 32 rotatable on the shaft 19.

It is evident that if the.-carrier 32 is free to revolve, rotary movement of the gear 28 will have no effect on the gear 29. If, however,

the carrier is held stationary, rotation of the gear v28 in 'one direction will turn the gear 29 in the opposite direction. Normally,

the carrier is held by a fork 32 engaging a roller stud 32, on. one side of said carrier, so that as the scale pan descends not only will the pointers 22.27 be moved over. their respective scales but also-the arm .34. fixed to the gear 29, will be swung along the arcshaped ratchet 35. When the scale pan and the-pointers come to rest the arm 34 also comes to re t: whereupon. by meanshereafter described. arm 34 is locked and'the carrier 32 is simultaneouslv unlocked. The arm 34 is therefore held in the position to which it was brought by the goods on the.

pan, but the pan itself is free. Hence if the Usalesman should surreptitiously remove any part of the goods from the pan the pointer would instantly reveal ,theLfact by swinging away from its former position. For the purpose of indicating .the position of thearm 34 both to'the salesman and to the customer. asecond differential mechanism is provided. comprising a bevel gear. 36 fixed on the hub of the'gear 29. a bevel gear 37 loose on the shaft 19. and a bevel pinion 38, rotatable on a stud fixed in the'bracket 39.

Fixed to the gear 37 is a pointer 40 extend- .ing up past the scale 25 and over upon the scale 23. Since the pinion 38rcannot revolve around the shaft 19 itwill be seen that the gear 37 and index 40 will move in unison with gear 29 and arm 34'and will come to rest and be locked with the latter although the scale pan and the pointers 22, 27, are free to move. As long as the two pointers 27 and 40 coincide the customer can be sure that the scale'pan contains the weight indicated. If the two do not coincide he knows that something is wrong.

The arm 34 is locked upon the arc-shaped ratchet or rack 35, which is provided with any suitable number'of teeth, say one tooth for each ounce. Thus in a machine with a capacity of five pounds the rack would have eighty teeth. On the end of the arm is a quadruple pawl 41 (Figs. 11 and 12) whose teeth 42, 43, 44, 45, are separated by spaces each equal to one-fourth the space between successive teeth on the rack 35, so that when, the arm 34 having come to rest, the pawl is permitted to swing up into engagement with the rack the arm will be locked to the rack at the position corresponding to the weight of material in the scale pan, within one-quarter ounce of the exact weight. That is, the maximum error in the position of the arm 34. is one-fourth of a tooth on the rack35, which error cor- ,responds to one-fourth of an ounce;- Of

course the limit of possible error depends upon the number of pawl-points provided in the space of one toothon the rack, and

may be made as large or as small as desired by decreasing or increasing the number of such pawl-points. or by varying the spacing of the rack-teeth and pawl-points. etc.

Normally the pawl 41 is held out of engag ment with the rack 35 by a' pin or stud 46 fixed to a slide 47 mounted on the arm 34. On the lower end of the slide is a stud 48. A spring 49 draws the slide downward, thereby de ress ng the pawl 41, and hold the stud 48 close to or against an arceshaped link 50 pivoted at one end on a pivoted arm 51 and at the other end pivotally connected to a bell-crank lever 52. Assum ng thelever 52 to be rocked counterclockwise -(as seen in Fig. 3) the link 50 will rise and o lift the slide- 47. thereby releasing the pawl 41. To prevent thestud 48 bearing too hard upon the link 50. or to ho d it normally out of'contact with the link, the downwardmovement of the slide 47 through the agency of the spring 49 is lim ted by a stop 53 on the arm 34.

- The movement of the lever 52, described in the foregoing paragraph, for the purpose ofreleasing the pawl 41 so that the nally by a crank 58.. Figs. 1. 7 and 8.

Having described how the arm 34' is locked in a position determined by the weight of the material in the pan we shall now explain one. method by which this locked arm ma v be utilized in effecting the desired computation. Briefly, in the preferred embodiment, the method referred to consists in coupling up to the cam 54 and segmental gear 55 a stop arm 60 (Fig. 3) which has a segmental gear 61 meshing with a rack 62 on a reciprocatory link movable in guide-slots in the fixed brackets 39 and 39. Thus it will be seen that when the shaft 57 is rocked (countercloclnvise as seen in Fig. 3) arm 60 will swing clockwise, until the pin 64 comes up against the stopplate 65 on the arm 34. thereby shifting the link 63 to the left a distance determined by the position of the arm 34. To permit the shaft 57 and segmental gears 56, 55, to continue their movement after the arm 60 and slide 63 have been arrested, the arm 60 and its segmental gear 61 are connected to the ear 55 through the medium of a spiral b spring 66, Flgs. 4 and 10, one end of which is attached to the gear 55 and the other to I the gear 61.

cam 07, Fig. 3, engaging a roller stud 68 on the fork 32. The latter being fulcrumed at 6-9 it will be seen that when the shaft 57 is rocked counterclockwise the cam 67 swings the fork out of engagement with the stud 32", on the .carrier 32. This releases the said carrier and leaves the scale free" as described above. A spring 70 urges the fork-into engagement with the stud 32".

As before stated, the extentof leftward movement of the link 63 depends upon the position of the abutment arm 34, which in turn depends upon the weight of the material in the scale pan. This differential movement of the link is utilized in the computing operation, preferably in the following manner. At its left end, Fig. 3, the said link is pivotally connected to an upright lever 71,.f'ulcrumed at 72 and urged in the counterclockwise direction by a spring 73. To insure release of the pawl 41 and consequent locking of the arm 34 before, the link 63 starts to swing the lever 71 th connection between the latter and the link (53 is made by means of the pin and horizontal slot construction shown, thus permitting a slight lost motion of the link before 'the lever starts to move. As the link begins its movement the pin 74 movesfout of the horizontal portion of the slot 75 and then against the ledge edge, of the vertical portion. after which the further movement of the link rocks the lever clockwise. The upper arm of the lever 71 has a long slot 7 6, engaged by a stud 77 ona horizontal slide or bar 78 slidably mounted in a carrier or support 79 which is itself mounted to slide vertically on a pair of guide bars or standards 80. It will therefore be seen that the extent of movement imparted to the slide or bar 78 by the lever 71 depends upon the position of the slide on the guides 80. When the slide is its uppermost position it. will have its maximum niovement, and will have its minimum movement when in the lower- InOSt'pOS11L10n. 0n the slide'or bar78 is a rack 81, meshing with a pinion 82 slidable axially on a vertical shaft 83. The latter is square in cross section so as to be rotated by the rack 81 when the bar 7 S is reciprocated, and has at its lower end a bevel gear 84 meshing with a bevel gear 85 connected to the disk 86. The result is that the extent of rotation of the disk 86 depends upon two factors: one, the weight of material in the scale pan, through the medium of the arms 34 and 60 and link 63; and the other the position of the slide or bar 78 on the vertical guides 80. The latter factor is, in the present embodiment of the invention, the rate or price per unit of weight, and is varied by adjusting the bar 78 up and down on the said guides. For this purpose the guide 79, in which the said-bar moves horizontally, is provided with a vertical rack 87 meshing with a gear-S8 fixed to a shaft 8!) which also has fixed to it a disk 90 graduatedat its edge (see Fig. 1) to indicate the various prices per uni-t of weight within the range of the machine. A handle or crank 91 (Fig. 5) fixed to the shaft 89 serves to rotate the shaft and thereby revolve the gear 88 and raise or lower the slide 78, at the same time causing the rate per unit weight to be visible to the customer at the front through the window 92 in the casing 11. The handle 91 is provided with an index or pointer 93, traversing a dial 94 graduated with the rates per unit weight. en-

abling the salesman to adjust the slide 78 with accuracy.

As will be seen from the foregoing explanation. the extent of rotary movement of the disk 86 and the final position thereof depend upon the conjoint effects of two fact0rs,-the weight of material in the scale pan and the rate or price per unit weight. Hence the movement of the disk may be availed of to indicate, both to the salesman and to the customer, the product of said factors. For the first-named purpose a simple and effective method is to provide the shaft 95, which carries the disk 86. with a second disk 96, Figs. 2 and 5, graduated at its edge with the various products. These graduations are visible through a window 97 in the back of the casing 11 and are read against an index 98.

To the customer the products are displayed preferably by means of a series of numeral wheels 100, 101, 10-2, Figs. 1', 6 and 14, visible through a window 103 in the front. of the casing 11. These wheels are mounted on a shaft 104 so as to be rotated independently of each other by means of vertically movable racks 105. 106, 107, meshing with pinions 108, 109, 110, on the respective numeral wheels. The racks are attached to the upperends of'three slides 111, 112, 113, movable vertically on a supporting plate 114, by means of springs 115, 116, 117. Manifestly, a greater or less numare held in their lowermost any group is brought into radial alinement elongated apertures 135, in

to the number of columns to be provided for in the products.

The upward movements of the slides 112, 113, and hencethe rotary movements of the numeral wheels 101, 102, are limited by vertically movable slides 118, 119, mounted on the supporting plate 114 and acting through the agency of levers 1 20, 121, fulcrumed on said plate.

Normally, all three slides 111, 112, 113, positions, with the numeral wheels all showing zero through the window 103, by means of a universal bar 1122 engaging pins 123, 124, 125, on the s ides, bar is carried-by a slide 126 mounted on the plate 114 and is drawn down against the tension of the elevating spring 127 by means of a lever 128' fulcrumed at 129. At its left end (as seen in Fig. 1) the lever has a stud 130 bearing on a cam 131 fixed to the main operating shaft 57 and so designed that as the cam 131'completes its rotary movement, asdescribed above, the drop 132 will come under the stud 130 and permit the lever to rock counterclockwise and the universal bar to rise under .the influence of the spring 127, thereby permitting the springs 115, 116, 117 to raisethe slides 111, the numeral wheels 100, 101, 102.

For the purpose of limiting the downward movements of the controlling slides 118, 119, to arrest the numeral wheels with the proper digits in line at the window 103, the disk 86 can be utilized in various ways, preferably the following.

Around the disk 86 are groups of perforations 133, Fig. 15, of ten perforations each,

there being as many groups of perforations as there are tens in the maximum product provided for by'the machine; 'The perforations may be located by drawing ten concentric circles on the disk and as many radiias there are units inzthe maximum product, a perforation being made at each intersection of a radius and a circumference. This makes each group of perforations form of a curved line as shown in Fig. 15, with the result that when any perforation in with the starting point of the disk, indicated by the dotted line 134 in Fig. 15, no other perforation in that group will be in such alinement. In like manner the disk 86 is provided with a series of circumferentially number equal to the number of tens in the maximum product and arranged in groups of ten each, the number of groups being equal to the number of hundreds in the maximum product.

Behind the disk 86 at the top thereof is a pin-box 136, Figs. 2, 5, 9 and 13, mounted on the upper end of a lever 137 fixed on a shaft the other side, the

(see Figs. 1 and 14). This universal ries. of

112, 113, and rotate 144 on the shaft take the dollars wheel 100.

i 5. 138. The pin-box has a vertical series of posltion indicated by the line 134 in Fig. 15, and pressd toward the disk 86 by coil springs 140. The spacing of the pins being the same as the radial separation of the perforations 133 in the aforesaid disk, it will be seen that when the pin-box is swung toward the disk by the arm 137 one of the pins, and only one, will find a perforation in its path, which perforation is determined by the extent of movement of the disk as already explained. Hence that particular pin will pass through the disk and protrude on other pins being arrested by the, disk itself. Then when the spring 117 (Fig. 14) raises the rack 107 the stopfinger 141 on the controlling slide 119 will strike'the protruding pin 139 and arrest the rackl07 and numeral wheel 102 with the proper digit at the window 103, corresponding to the perforation through which the aforesaid pin projects.

The pin-box 136 has a second vertical sepins, 142, to cotiperate with the apertures 135 in the disk 86, so that when the pin- :box is swung toward the disk one of the pins 142 will project through the appropriate aperture and into the pathof the stop :llinger 143 (Fig. 14) on the controlling slide 18. numeral wheel 101 (through themedium of the slide 112 and rack 106) the numeral wheel will be arrested with the proper digit in line at the window 103. i The pin-box 136 is swung toward the disk, fort-he purpose explained above, by a cam 57, which, it will beremmbere'd, is actuated by the crank or handle 58. On the shaft 138, to which the arm 137 is fixed, is an operating arm 145 cotiperating with the cam 144 so that when the same is rocked by the shaft 57 the shaft 138 will be rocked andthe pin-box 136 swung over toward the disk 86. It will be understood that the can 144 is timed to swing the apertures in the disk 86, to take care of the" numeral wheel 100, we prefer to employ the followingmeans for the purpose.

Fixed to the bevel gear 85, Figs. 5 and 14, is a hundreds or dollars cam 146 having three configurations, in the 'present' instance drops.- On this cam bears the end of a lever 147, connected to the slide. 111 which, it will be remembered, is drawn up by the spring 115 to rotate the hundreds or For any product less ten;pins 139 arranged 'in register with the ence when the spring 116 rotates the thanpne hundred (cents) the cam is in the position shown in Fig.14 and the slide 111 is held down, with zero appearing on the dollars wheel at the window 103. When, however, the product a-mounts to one hundred or more but less than two hundred (cents) the cam 146, turning in unison with the disk 86, brings the first drop under the lever, with the result that upon release of the pin 123 by the universal bar 122 the slide 111 is' raised, thereby turning the numeral wheel 100 one step and causing the digit 1 to appear at the window. Further movements of the cam bring the second and third drops under the lever and permit the numerals 2 and 3 to be displayed on the dollars wheel.

For the purpose of locking the disk 86 positively in adjusted position it is provided on its periphery with notches 148, one for each perforation 133 and in radial alinement with the notched periphery of the disk is a lever 149, Fig. 3, fulcrumed at 150 and having a stud 151 which is caused to bear on the cam 152 by a spring 153. The cam being fixed to the shaft 57 it will be seen that when the latter is rocked by the handle 58 the cam will be rocked counterclockwise (as seen in Fig. 3), thereby swinging the lever 149 in the same direction and causing its pointed end 154 to move into the notch presented to it. By making the notches148 and pointed end 154 V-shaped, as shown, the lever can be made to serve as a justifying element, to accurately position the disk 86 as well as to lock it in position. The cam 152 is timed to rock the lever just after the disk 86.is.arrested by the arm 60 striking the stop 65 on the arm 34 as previously described.

In operating the machine the salesman may firstset the pointer 93 to the rate or price at which the goods are to be sold or he may first deposit the goods in the scale pan. Setting the pointer 93 raises or lowers the slide 78 (Fig. 3 andso alters the distance through whic the slide will subsequently be moved by the lever 71. In Fig. 3 we have indicated by dotted lines the positions of the slide 78 at rates or prices ranging up to sixty cents per pound. The goods to be sold having been placed in the scale pan, their weight swings the arm 34 clockwise (as seen in Fig. '3) \Vhen the pointers 22. 27. and 40 have come to rest (and with them the arm 34) the operator depresses the handle 58. The first effect of this movement is to release the part 32, so that thereafter the scale pan will be free as it was before. At the same time the cam 54 raises the link 50 and releases the pawl 41, which instantly locks the arm 34 to the rack 35. Next the segmental gear 61 moves the link 63 toward the left and thereby shifts the slide 7 8 toward the right through the medium of the lever 72 until the arm 60 is arrested by the stop 65 on arm 34. This movement of the slide 78 rotates the disk 86 and cam 146 clockwise (as seen in Fig. 3) and brings to the pin-box 136 the proper perforation 133 and aperture 135 in the disk 86 and also adjusts the cam 146. Next the cam 152 swings the lever 149 over into locking engagement with the disk 86, so that the latter and the dollars cam 146 cannot move. The cam 144, Fig. 2, now swings the pin-box 136 against the disk 86, causing one pin from each group 139, 143, to pass through the adjacent opening in the disk, and as soon as this operation is completed the cam 131 (Fig. 1) permits the spring 127 (Fig. 14) to raise the universal bar 122. As the latter rises the springs 115, 116, 117, lift the slides 111, 112, 113, and so rotate the numeral wheels 100, 101, 102, until the slides 118, 119, are arrested by the projecting pins 142, 139, and the lever 147 by the cam 146. The product, that is, the total price of the goods in the pan at the given rate or price per pound, having been noted, the handle 58. is released, whereupon the spring 155", Fig. 3, returns the parts to.'initial position, aided by such other springs as were under tension during the operations described. The slide 78, however, is left "in the position to which it had been set. Obviously it is not necessary to return the slide to the bottomof the guides 80 at the end of each cycle, since the slide can be set to any new position from any position at which it may happen to be.

It Will be observed that the leftward movement of the link 63 is always equal to the actual arc traversed by the swinging gear 61, which, it will be remembered moves. in unison with the arm 34. Moreover, the pins 74 and 77 engage the lever 71 in the slots 7 5 and 76. Hence the lower arm of the lever (initially at right angles to the path of the link 63) always forms the hypotenuse of a right-triangle whose base is traversed by the pin 74. Likewise, the upper arm of the lever always forms the hypotenuse of a triangle whose base is traversed by the pin 77. Since in these triangles the angles which meet at the fulcrum of the lever are always equal, one to the other, the triangles are always similaiyi and consequently the movement of the slide 78, at any given distance thereof from the fulcrum, is always proportional to the arc through which the gear 61 swings. It will therefore be seen that the machine described comprises: (1) An element which is adjusted in one direction through a distance which is proportional to the value of one of the items of the computation, and is also movable in a direction at an angle to the first; for example the slide 78. element to actuate or move the first element in the second-named direction; as for example the lever 71. And (3), means, for example the slide 63 and gear 61, for so actuating the second named element as to move the first (at any given position of adjustment thereof) through a space proportional to another item of the computation. The first element controls the product-displaying mechanism, the control in 'the resent case being indirect through. the medium of the disk 86.

' the multiplication in contradist-inction to at 160 and is provided with a knob 161 prohave been brought into coincidence with devices of that class which merely take off a reading of a computation already made elsewhere and by independent means. The

.term computing multiplying device will also be understood to distingulsh from devices which are in reality a multiplication table andin which the computed result is attained by a selection of a particular number or numbers already 'present in the multiplication table device. In further explanation it may be stated that a computing multiplying device-is adapted to take a setting of one factor and a setting movement corresponding to another factor and carry out by some suitable means a mechanical multiplication of the factors to attain a desired product.

The machine illustrated in Figs. 17, 18, 19, 20 and 21 is a simpler form of the invention, made simpler by omitting the arm 34 and the parts which actuate it, and by the 0II11SS10I1 of certain other parts. In Fig. 17 the arm of Fig. 3 takes the form shown jecting through an 'arc -shaped slot 162 in the casing 11. When the pointers 22, 27, actuated by the scale beam 14, have come to rest, the'operator swings the arm 160 by I means of the knob 161 till the pointers 163,

carried by the arm 160, coincide with the a trolling element; motive power means lndepointers 22. 27. The arm 160 is loose on the shaft 164 but is rigidly connected with a segmental gear 165 meshing with a doublesegmentalgear 166 whichalso meshes with the rack 167 on the end of link 168, corresponding to the link 63 in Fig. 3. The

described movement of the arm 160 therefore rocks the lever 169.. The latter, slide 170 actuated by it, and the parts actuated by the slide, are in all respects the same as those described" in connection with Figs. 1 to 16 inclusive, and hence need no further description here. When the pointers 163 pointers 22, 27, the operator swings the handle 171. The first effect of this operation is to rock the pin-box 172 through the agency of cam 173, arm 174, and shaft 175. The cam 176 then rocks the lever 177, which raises the slide 178 carrying the universal bar 179. This releases the numeral-wheelactuating slides 180,181, 182, whereupon the numeral wheels 183, 184, 185, are set exactly as described in connection with thesimilar parts in Figs. 1 to 16.

A still simpler form .of the invention,

unconnected with a scale for weighing goods, is shown in Figs. 22, 23, 24, and 25.

In this form, as in the others described herein, one of the factors is set up by ad- ]ustlng the slide 190 vertically movement of the slide by the lever 191. The other factor is taken account of by setting the pointer 192, which rocks the lever 191, through the medium of the segmental gears 193, 194, and rack-link 195, and rotates the apertured disk 196 and hundredscam 196 as the slide 190 is shifted by the aforesaid lever. 'These operations having by means of the handle 190, thus varying the extent of been performed, the operator depresses the handle 197. This first rocks the cam 198 and swings the pin-box 199 against the disk 196, after which the cam 200, fixed on the shaft 201 raises the universal bar 202, releasing the slides 203, 204, 205, and permitting the said slides to rise and set the numeral wheels 206, 207 208. This form of the invention finds utility in various fields, as for example in cost-keeping, where it is desired to multiply numbers representing time by numbers representing labor-cost per unit of time.

As previously intimated, the invention is by no means limited to the machines specifically illustrated and described herein, but may be embodied in a variety of other forms without departing from its proper spirit and scope.

' What we claim is:

1. In a computing scale, the combination of an adjustable controlling element; means adjustable in accordance with the product of the weight on the scale and another fac tor to determine the adjustment of the conmovable in one direction to actuate the said element and adjustable in a direction at an angle to the first. a device movable through a space proportional to the value of one of said factors and connected with said member to actuate the same,'motive power means for operating thesaid device independently of the.motive 'power of the scale but controlled in its extent of movement thereby,

said motive power means being adapted to thereafter restore the device to normal position, and means for adjusting the actuating member to an extent proportional to the value of the other factor to vary the extent of movement imparted to said member by the aforesaid device.

3. I11 a computing scale, the combination of a member movable in one direction, and capable of adjustment in a direction at an angle to the first in accordance with the value of an item of the computation; a movable actuating element connected with said member to move the same in the first named direction to a position determined coujointly by the adjustn'ient of said member and the extent of movement of the actuating clement. itself, and means controlled by the scale but operable by a source of motive power independent of the motive power of the scale for moving the actuating element through a'space proportional to the weight on the scale constituting the value of another item of the computation.

4. In a computing scale, the combination of a member movable in one direction, and adjustable in another direction at an angle to the first; means, including a graduated scale, for adjusting the member in accordance with the value of one item of the computation; a lever to which the member is adjustably connected for movement thereby 1n the first-named direction; motive power means lndependent of the inotlve powerof 'the scale; means for rocking the lever in accordance with the weight on scale constituting the value of another item of the computation; whereby the extent of movement of said member is determined by said items conjointly; and means controlled by said member for displaying the result of the computation.

5. In a computing scale, the combination with a scale-moved part, a member bodily movable in one direction in direct accordance with the weight on the scale and adjustable in a direction at an angle to he first in accordance with the price per pound of, the commodity weighed, motive power means independent of the scale and includmg a resilient lost motion operatmg concordance with the extent of movement of the scale-moved part, and a controlling device from which readings of computed.

costs may be taken, said controlling device being adapted to be moved by said member to an extent determined jointly by the/extent of adjustment of said member and the movement imparted thereto by the aforesaid means.

6. In a computing scale, the combination of' a weighing scale, an actuating lever; a slide connected therewith for actuation and adjustable relatively to the fulcrum of the --lever; means for rocking the lever through various angles to correspond with the' weight on the scale; a rotary disk connected with the 'slide for rotation thereby, and

having digit-perforations located according to the values of the digits; and means controlled by said perforations to display the results of the computations.

7. In a computing scale, the combination of a weighing scale, a movable controlling element having digit-openings located in accordance with the values of the digits; means for moving the controlling element through a space substantially proportional to the product of two factors, one of said factors being proportional to the weight on the scale; a pin-box movable toward and from the controlling element and having a plurality of digit-pins each adapted to project through an appropriate perforation when the same is presented in the path of the pin; and product-displaying means controlled by the projecting pin or pins.

8. In a computing scale, the combination .of a weighing scale, a rotary disk having radially and angularly spaced groups of radially and angularly spaced perforations.

corresponding to digits of different notational orders; means for rotating the disk through an angle substantially proportional to the product of the weight on the scale and another factor; a pin-box movable toward and from the disk and having spaced groups of spaced pins arrangedeto permit a single pin of each group to project through an appropriate perforation in the perforations therein. nection for operatmg said member in 'ac- 10. In a computing scale, a rotary disk having radially and angularly spaced groups of radially and angularly spaced digit-perforations; weighing scale means and manually operated price per pound setting means; means for turning the disk through an angle corresponding to 'the product of factors, one factor being proportional to price and the other proportional to the weight on the scale; and Product-disand movablein correspondence with the respective wheels, a controlling element movable past the sliding members and having spaced groups of digit-perforations, and

parts coiip'erating with the sliding members through perforations in the controlling element to arrest the sliding members; and means associated with the scale for moving the controlling, element past the sliding members proportionally to the product of factors at least one of which is variable.

12. Ina computing scale, the combination of a weighing scale, product-displaying wheels; sliding members connected with the wheels; mechanism, including a movable controlling element having spaced groups of digit perforations and parts adapted to coiiperate with said sliding members through perforations in said element to determine the rotary movements of said numeral wheels; and means for moving the controlling element proportionately to the product of factors at least one of which is -weight on the scale.

variable in accordance with the va 13; In a computing scale, the combination of a weighing scale; numeral wheels; means for rotating the wheels; controlling slides connected with the wheels; a disk rotatable past the controlling slides and having spacedgroups of digit perforations; parts movable through'perforations in the disk and into the paths of the controlling slides .to arrest the same and therebyarrest the box movable toward and from the face of the wheels; and scale controlled means for ro-- tating the diskpast the controlling slides p'roportionately'to the product of factors at least one of which is variable.

145. In a computing scale, the combination of a weighing scale, a rotary disk having spaced groups of digit-perforations; apindisk and provided with pins adapted to project through the perforations; means forturningthe disk past the pin-box proportionately to the product of factors at least one of which is variable in accordance with.

the 'weight 'on' the scale; numeral wheels for displayingsuch product; means for ro-' 'tating the wheels in one direction; controlling slides movable with the wheels in paths crossing th paths of the pins through the disk, whereby to meet and-be arrested by projecting pins; and means for restoring the wheels and slides to initial position.

15. In a computing scale, the combination 7 of a weighing scale, a horizontally movah le slide, a vertically adjustable support therefor, a vertical lever to which the slide isadjustably connected, an actuating member connected 'with the lever and controlled .in its extent of movement by the weighing scale,

a rotary disk having digit-perforations, means connecting the slide and the disk to rotate the latter, and product-displaying means controlled by said disk through the agency of the digit-perforations.

16, Ina computing scale, the combination of a Weighing scale, a vertical lever, a vertically adjustable carrier or support, a bar mounted in the carrier to slide horizontally therein and slidably connected with the lever for actuation thereby, a link slidably connected with the lever to rock the same. a,

rotary disk having digit-perforations and by, product-displaying mechanism controlled by the disk through the agency of said perforations, means to adjust the carrier and slide toward and from the fulcrum of the lever in accordance with the value of a fac-,

tor to be multiplied, and means to actuate the link. in accordance with the value of an other factor proportional to the weight on the scale.

17. In a'computing scale, the combination of a weighing scale, a movabl controlling member having digit perforations for a lower notational order; a cam having digitconfigurations for a higher notational or- "der; means for moving said disk and cam ,turning the disk and cam through an angle corresponding to the weight upon the scale and the price per pound of the commodity Weighed; and product-displaying means controlled-by the disk and cam through the agency of the perforations and configurations thereof.

19. In a computing scale, the combination of a movable controlling element having digit, perforations; productdisplaying mechanism controlled by said through the agency of the perforations therein; means for moving the controlling member through a space corresponding to the product of factors at least one of whichis variable, said means including an adjust able stop-member to determine the movement of said element, and weight-actuated mechanism releasably connected with the locking the stop-member in adjusted position; and means for releasing the stop-member from the weight-actuated mechanism.

20. In a computing scale, the combination of a movable controlling element in the form element;

connected with the slide for rotation there:

. stop-member to adjust the same;means for 

